Streptococcus mutans P1 Adhesin - American Chemical Society

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Binding Forces of Streptococcus mutans P1 Adhesin ^ ne*,† Ruby May A. Sullan,†,# James K. Li,‡ Paula J. Crowley,§ L. Jeannine Brady,*,§ and Yves F. Dufre †

Institute of Life Sciences, Université Catholique de Louvain, Louvain-la-Neuve, Belgium B-1348, ‡Institute for Optical Sciences, University of Toronto, Toronto, Ontario M5S 3H8, Canada, and §Department of Oral Biology, University of Florida, Gainesville, Florida 32603, United States. #Present address: Mechano(bio)chemistry Group, Max Planck Institute of Colloids and Interfaces, Potsdam, 14476, Germany.

ABSTRACT Streptococcus mutans is a Gram-positive oral bacte-

rium that is a primary etiological agent associated with human dental caries. In the oral cavity, S. mutans adheres to immobilized salivary agglutinin (SAG) contained within the salivary pellicle on the tooth surface. Binding to SAG is mediated by cell surface P1, a multifunctional adhesin that is also capable of interacting with extracellular matrix proteins. This may be of particular importance outside of the oral cavity as S. mutans has been associated with infective endocarditis and detected in atherosclerotic plaque. Despite the biomedical importance of P1, its binding mechanisms are not completely understood. In this work, we use atomic force microscopy-based single-molecule and single-cell force spectroscopy to quantify the nanoscale forces driving P1-mediated adhesion. Single-molecule experiments show that full-length P1, as well as fragments containing only the P1 globular head or C-terminal region, binds to SAG with relatively weak forces (∼50 pN). In contrast, single-cell analyses reveal that adhesion of a single S. mutans cell to SAG is mediated by strong (∼500 pN) and long-range (up to 6000 nm) forces. This is likely due to the binding of multiple P1 adhesins to self-associated gp340 glycoproteins. Such a cooperative, long-range character of the S. mutans
SAG interaction would therefore dramatically increase the strength and duration of cell adhesion. We also demonstrate, at single-molecule and single-cell levels, the interaction of P1 with fibronectin and collagen, as well as with hydrophobic, but not hydrophilic, substrates. The binding mechanism (strong forces, cooperativity, broad specificity) of P1 provides a molecular basis for its multifunctional adhesion properties. Our methodology represents a valuable approach to probe the binding forces of bacterial adhesins and offers a tractable methodology to assess anti-adhesion therapy. KEYWORDS: Streptococcus mutans . AFM . single-cell force spectroscopy . single-molecule force spectroscopy . bacterial adhesion . salivary agglutinin . P1 . antigen I/II

Streptococcus mutans is an acidogenic Gram-positive oral bacterium that is a primary disease-causing agent associated with tooth decay.1 In the oral cavity, S. mutans colonization depends on sucrosedependent as well as sucrose-independent mechanisms. Sucrose-independent adhesion of S. mutans cells to tooth surfaces involves cell surface proteins such as the cell wall-anchored adhesin P1 (also referred to as Ag I/II, PAc, SpaP or antigen B).2
6 P1 is a multifunctional adhesin that contributes to S. mutans' ability to adhere to tooth pellicles and cause tooth decay.7
13 In addition to its etiologic association with human dental caries, S. mutans has also been linked to cases of bacterial endocarditis and has been detected in atherosclerotic plaque.14
16 Some strains of S. mutans have been reported to invade human coronary endothelial cells.17,18 In the oral environment, P1 interacts primarily with the glycoprotein salivary agglutinin (SAG) SULLAN ET AL.

complex predominantly composed of the scavenger receptor glycoprotein 340 (gp340/DMBT1), contained within the salivary pellicle on tooth surfaces.2,4,5,19
23 P1 has also been shown to bind to extracellular matrix proteins such as collagen (Coll)24
27 and fibronectin (Fn),26,28,29 and is involved in cell
cell adhesion as well.30 The ability of P1 to promote bacterial adherence and to affect colonization, cariogenicity and biofilm formation has made it of interest as a therapeutic target.20,31
34 The primary amino acid sequence of P1 consists of a signal sequence, an N-terminal region, alanine-rich repeats (A1
3), an intervening segment containing a variable (V) region, proline-rich repeats (P1
3), C-terminal region consisting of three domains (C1
3,) and a wall-spanning region.35,36 A structural model of P1 derived from crystal structures demonstrates that the A-repeats form a long R-helix that intimately intertwines into VOL. XXX

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* Address correspondence to [email protected], [email protected]fl.edu. Received for review October 15, 2014 and accepted January 30, 2015. Published online 10.1021/nn5058886 C XXXX American Chemical Society

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SULLAN ET AL.

possible to quantify adhesive interactions on a singlecell basis. New protocols have been developed for the reliable SCFS analysis of microbes. One approach is FluidFM, where hollow AFM probes with nanoscale apertures are used for manipulating and probing individual cells.45 Another assay for reliable single microbial cell manipulation uses colloidal probes coated with bioinspired polydopamine wet adhesive.46 Currently, an exciting challenge is to combine SMFS and SCFS to gain insight into the binding mechanisms of adhesins. In one such study, Herman et al.47 probed the binding strength of the SdrG adhesin from Staphylococcus epidermidis, revealing that it binds to the blood plasma protein fibrinogen with a strength equivalent to that of a covalent bond, thus much larger than the force of any adhesin investigated so far. Here, we used SMFS and SCFS techniques to unravel the nanoscale adhesion forces between S. mutans P1 and target receptors (SAG, Fn and Coll) as well as to hydrophobic and hydrophilic substrates.

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a left-handed supercoiled structure with the helical polyproline P-repeats to form an unusually long and narrow stalk.37 A β-rich “globular head” domain, predicted to contain a carbohydrate-binding trench, intervenes the A- and P-repeats at the tip of the extended stalk. The C-terminal region is also globular and comprised of three structurally related β-sandwich domains stabilized by covalent isopeptide bonds.38,39 Within the context of the complete fully folded molecule, this region resides at the opposite end of the stalk. In addition to its unusual tertiary structure, our recent work has demonstrated that a complex ultrastructure of P1 also exists on the cell surface such that a scaffold of covalently attached P1 interacts with more loosely associated adhesive P1 fragments, including the C-terminal fragment previously identified as Antigen II,40 to form the functional adhesive layer. Various techniques have been used to locate binding domains within both P1 and SAG. An earlier study using a sandwich-type assay, identified the N-terminal segment of P1 (PAc) as a saliva-binding region.41 A subsequent study employing Scatchard analysis suggested the presence of two binding sites within P1 (Ag I/II).20 More recently, surface plasmon resonance (SPR) was used to demonstrate that the apical head region (A3VP1) and the C-terminal fragment (C1
3) each are capable of independent and noncompetitive adherence to immobilized SAG.37 The same group specifically identified the scavenger rich cysteine repeat (SRCR) domains of gp340 as the binding sites within SAG to which A3VP1 and C-terminal P1 fragments adhere.22 It was further shown that calcium-dependent adherence of P1 to SAG stems from calcium-induced conformational changes in the SRCR domains of gp340 that increase their thermal stability.22 Though the aforementioned studies shed light on the adhesion of P1 to the SAG glycoprotein complex, the binding forces involved in the interaction of P1 to SAG as well as to other extracellular matrix proteins have yet to be quantified and the molecular mechanisms fully elucidated. Atomic force microscopy (AFM) offers unprecedented opportunities for exploring the forces involved in microbial cell adhesion and biofilm formation. Singlemolecule force spectroscopy (SMFS) with biospecific AFM tips allows researchers to gain insight into the localization, binding strength and elasticity of individual adhesins, either on purified systems or on live cells. In the pathogenesis context, examples of thoroughly investigated adhesins are the mycobacterial heparin-binding hemagglutinin adhesin (HBHA),42 the agglutinin-like sequence (Als) proteins from Candida albicans,43 and fibronectin binding proteins (FnBPs) from Staphylococcus aureus.44 In addition, single-cell force spectroscopy (SCFS), in which AFM cantilevers are functionalized with microbial cells, makes it

RESULTS AND DISCUSSION Strength of Single P1
SAG Bonds. SMFS was used to understand how P1 adhesins adhere to salivary components and extracellular matrix molecules at the molecular level. We measured the forces between AFM tips functionalized with complete P1 molecules or P1 fragments (globular head, C-terminal region) and SAG proteins randomly immobilized on solid substrates (Figure 1a, inset). To ensure single-adhesin detection, the tip was functionalized with a PEGbenzaldehyde linker using a well-established protocol.48 The adhesion force and rupture length histograms, as well as representative retraction force curves obtained at a pulling speed of 1000 nm s
1 for the P1
SAG interaction, are shown in Figure 1a
c. Considerable (∼30%) binding events were observed with adhesion forces in the range of 30
200 pN. The most probable force was 57 ( 30 pN (mean values and SD from five independent experiments), a value in the range of the forces reported for other adhesins at similar loading rate (i.e., the rate at which the force is applied to the complex).49 To test the specificity of binding, we blocked the P1-tip using an anti-P1 antibody (mAb 1-6F)50 directed against the head region (Figure 1d-f).51 We observed a substantial decrease in binding frequency (down to ∼9%) and in rupture length (